Studies on the Cell Wall of Chlorella V. Comparison of the Cell Wall Chemical Compositions in Strains of Chlorella ellipsoidea

Cell walls of four strains of Chlorella ellipsoidea (IAM C-27,C-87, C-102 and C-183) were compared as to their chemical compositions.Many differences were found: (1) The sugar composition of alkali-soluble cell walls differedin quantity as well as quality with glucuronic acid being foundonly in C-27 and C-87. (2) In alkali-insoluble cell walls glucosamine was found onlyin C-27. The other three strains contained mainly glucose. (3) The amino acid compositions of the alkali-insoluble cellwalls markedly differed among the four strains. The cell wallof C-102 contained more amino acids than carbohydrates, butC-27 and C-87 contained extremely little amino acid. In addition to the variation in cell wall composition, the opticalanisotropy findings also differed for these cell walls of Chlorellastrains which had been grouped as the same species. (Received August 16, 1983; Accepted December 27, 1983)     

The cell wall of Fusarium oxysporum.

Sugar analysis of isolated cell walls from three formae speciales of Fusarium oxysporum showed that they contained not only glucose and (N-acetyl)-glucosamine, but also mannose, galactose, and uronic acids, presumably originating from cell wall glycoproteins. Cell wall glycoproteins accounted for 50-60% of the total mass of the wall. X-ray diffraction studies showed the presence of alpha-1, 3-glucan in the alkali-soluble cell wall fraction and of beta-1, 3-glucan and chitin in the alkali-insoluble fraction. Electron microscopy and lectin binding studies indicated that glycoproteins form an external layer covering an inner layer composed of chitin and glucan.     

Chemical characterization of the hyphal walls of the basidiomyceteArmillaria mellea

Purified hyphal walls ofArmillaria mellea were analyzed and shown to contain glucose (59.0%), mannose (6.9%), galactose (4.2%), xylose (0.2%), ribose (traces), glucosamine (6.7%), protein (10.5%), and some lipid material (8.0%). The mucilaginous surface polysaccharide (fraction I) consisted mainly of (1–3), (1–4), and (1–6)β-glucan chains with mannose, galactose, xylose, and ribose. Fraction II was made mostly of (1–3)-linkedα-glucan. Fraction III contained mainly (1–3)-linkedβ-glucan with small amounts of mannose and galactose, and fraction IV was an alkali-insolubleβ(1–3)-glucan in close association with chitin.     

The Cell Wall of Fusarium oxysporum

Sugar analysis of isolated cell walls from three formae speciales of Fusarium oxysporum showed that they contained not only glucose and (N-acetyl)-glucosamine, but also mannose, galactose, and uronic acids, presumably originating from cell wall glycoproteins. Cell wall glycoproteins accounted for 50–60% of the total mass of the wall. X-ray diffraction studies showed the presence of α-1,3-glucan in the alkali-soluble cell wall fraction and of β-1,3-glucan and chitin in the alkali-insoluble fraction. Electron microscopy and lectin binding studies indicated that glycoproteins form an external layer covering an inner layer composed of chitin and glucan.     

Cell wall composition in the ascomycete sphaerostilbe repens at different developmental stages

Changes in the biochemical composition of isolated cell walls were analysed during the differentiation of coremia and rhizomorphs in Sphaerostilbe repens.Differentiation was accompanied by exclusively quantitative variations of the wall components: the content in carbohydrates, chitin and free amino sugars increased; on the contrary, amino acids, uronic acids, lipids and mineral substances decreased.Carbohydrates were composed of glucose, galactose and mannose; glucosamine was the main component of amino sugars. The predominant amino acid in the walls was cysteine the amount of which increased during hyphal aggregation, while quantities of the sixteen other determined amino acids decreased.Mineral matter was present in large quantities in the walls of the fungus, especially in vegetative mycelium. Iron, phosphorus and calcium were the most abundant elements.Possible relations between the variations in chemical composition of the wall and the capability of hyphae to aggregate are discussed.     

Chemical Studies on the Cell Walls of Leptospira biflexa Strain Urawa and Treponema pallidum Strain Reiter

The preparation and chemical poperties of the cell walls of Leptospira biflexa Urawa and Treponema pallidum Reiter are described. Both cell walls are composed mainly of polysaccharides and peptidoglycans. The data of chemical analysis indicate that the cell wall of L. biflexa Urawa contains rhamnose, arabinose, xylose, mannose, galactose, glucose and unidentified sugars as neutral sugars, and alanine, glutamic acid, α,ε-diaminopimelic acid, glucosamine and muramic acid as major amino acids and amino sugars. As major chemical constituents of the cell wall of T. pallidum Reiter, rhamnose, arabinose, xylose, mannose, galactose, glucose, alanine, glutamic acid, ornithine, glycine, glucosamine and muramic acid have been detected. The chemical properties of protein and polysaccharide fractions prepared from the cells of T. pallidum Reiter were also partially examined.     

Studies of the cell walls of Schizophyllum commune

Mechanically isolated cell wall materials of eight strains of Schizophyllum commune were studied by chemical and enzymatic procedures. Isolated wall material of each strain was separated by chemical methods into three fractions: A (cold alkali-soluble, , amorphous), B (warm alkali-soluble, amorphous), and C (alkali-insoluble, retaining appearance of hyphal fragments). Chemical tests indicated the presence of chitin in Fraction C and the absence of cellulose, lignin and pectic substances from all fractions. Analyses of acid hydrolysates indicated the presence of glucose in Fractions A, B and C, of hexosamine in Fraction C and the absence of galactose, mannose, 6-deoxyhexoses, xylose and other pentoses from all fractions. Unfractionated material, Fraction A and Fraction B were slightly attacked by commercial cellulase whereas Fraction C was heavily attacked. Commercial chitinase by itself did not attack Fraction C or unfractionated material to a significant extent. In the presence of cellulase, it was active upon Fraction C. Qualitative differences in cell wall composition between strains were not detected; however, quantitative differences were observed in the proportion of Fraction A and Fraction C as well as in the amount of the various breakdown products in certain strains. It is visualized that the cell wall of this fungus consists of a core of chitin covered by or intermeshed with glucose-containing polymers.     

Natural Abundance 13C Nuclear Magnetic Resonance Spectra of Intact Fungal Mycelia

We examined the change of the composition of the cell wall polysaccharides prepared from cells of the salt-tolerant yeast Zygosaccharomyces rouxii grown in two media containing 20% NaCl and 0% NaCl. Comparative analysis of their walls showed that the wall obtained from salt-free medium had greater quantities of alkali-insoluble fraction and smaller quantities of mannan than the walls obtained from 20% NaCl medium. The alkali-insoluble fractions from the cell walls obtained from salt-free medium contained a large amount of glucosamine and a smaller amount of linear β-1,3-glucosidic linkage than the fractions from the cell walls obtained from 20% NaCl medium. Structural analyses showed that the mannans from each cell wall contained an α-1,6-mannbsidic linked backbone to which single mannose and mannobiose units were connected as side chains by α-1,2-mannosidic linkages. However, when cells were grown in the presence of 20% NaCl, the side chains of the mannans consisting of a mannobiose unit were largely reduced.

These results indicated that the structure of alkali-insoluble glucan and mannan were greatly affected by the presence of NaCl in the final medium.     

Cell wall polysaccharides from Talaromyces species

The neutral sugars and amino sugars, released by acid hydrolysis of walls and polysaccharidic fractions, of six species of Talaromyces and the infrared spectra have been used to study their interspecific relationships. In whole cell walls neutral sugars ranged from 23 to 39.6% dry weight and were identified as glucose, galactose and mannose. Glucosamine varied from 8 to 19.8% in the samples. Galactosamine (2% or less) was found in T. emersonii and T. rotundus and no galactosamine in the other species. Sequential fractionation of the cell walls with alkali and acid gave several polysaccharidic fractions. The main differences among species were found in the alkali-soluble fraction at 20° (F1). This fraction represented 8 to 33.2% of the whole cell wall and was characterized as an -glucan in T. bacillisporus, T. emersonii, T. luteus and T. rotundus (Group A) and as a -galactofuranosyl containing glucan in T. ohiensis and T. stipitatus (Group B). The alkali-insoluble residue (F4) represented the bulk of the cell wall in all species tested (33.2% to 57.3%) and was characterized as a -glucan/chitin complex. The results may indicate degrees of interspecific relationship in the genus Talaromyces.Abbreviations CWM cell wall material - GLC gas-liquid chromatography - IR infrared - wt weight - CBS Centraal Bureau voor Schimmelcultures (Baarn. The Netherlands) - Ara arabinose - Xyl xylose - Man mannose - Gal galactose - Glc glucose - GlcNH₂ glucosamine - GalNH₂ galactosamine     

Differentiation and wall chemistry of Agaricus bisporus vegetative and aggregated micelia

Changes in the chemical composition of isolated cell walls and fractions were encountered during the differentiation of vegetative and aggregated mycelia of Agaricus bisporus.Differentiation was accompanied by quantitative variations of the wall polysaccharidic components. Neutral carbohydrates were composed of glucose, galactose, mannose and xylose and glucosamine as the only amino sugar. Differences in wall chemistry were correlated to the secondary and tertiary mycelial forms.     

Induced Autolysis of Aspergillus oryzae (A. niger group): IV. Carbohydrates

The examination of substances formed during induced autolysis by Aspergillus niger was continued in this work, which dealt in particular with carbohydrates. The autolysate contained a large amount of d-glucose (14 to 20% dry wt) and traces of glycolic aldehyde, dihydroxyacetone, ribose, xylose, and fructose. It also contained glycopeptides (about 10% dry wt), which were split from the cell wall during autolysis and which differed from one another in their level of polymerization and their composition. They were constituted by glucose and mannose, glucose and galactose, or mannose, glucose, and galactose (mannose being the most abundant in this case), and amino acids (chiefly alanine, serine, glutamic acid, and aspartic acid). During autolysis, only a part of the cell wall was dissolved, since it retained its shape. Upon further chemical hydrolysis, it produced mostly glucose and glucosamine, and smaller amounts of mannose, galactose, and amino acids. Presumably, glucomannoproteins and glucogalactoproteins were present in the intact cell as a macromolecular complex, constituting, together with chitin, the major part of the cell wall of Aspergillus.     

Resistance of Zygorhynchus Species to Lysis

Zygorhynchus vuilleminii, a nonmelanin-containing fungus, was not lysed by mycolytic actinomycetes. Several enzymes and Streptomyces enzyme preparations digesting walls of other fungi were without appreciable activity on walls of Zygorhynchus species. A bacterium able to solubilize a portion of the Zygorhynchus wall released little or no reducing sugars from these structures. Fractions of Z. vuilleminii walls were resistant to glucanase hydrolysis, but certain fractions were digested by chitinase and microbial enzyme preparations. The walls and several wall fractions were not readily susceptible to degradation by a soil community. Walls of lysis-resistant Zygorhynchus species contained glucosamine, fucose, glucuronic acid, and galactose but little or no glucose. Resistant wall fractions were rich in uronic acid and fucose, whereas the readily degradable fractions contained abundant glucosamine. Cultural conditions affected the extent of digestion and composition of the walls. Possible reasons for the resistance of Zygorhynchus to lysis in nature are discussed.     

Locus-specific Changes in Cell Wall Composition Characteristic of Osmotic Mutants of Neurospora crassa

The osmotic phenotype of Neurospora crassa is characterized by inhibition of growth at high osmolalities of growth medium. Mutations at six osmotic loci of linkage group I were examined to assess the biochemical and physiological effects of these mutants. Isolated cell walls from 23 osmotic strains were compared with the wild type with regard to quantitative levels of the following components: percentage of total dry weight, total glucose, alkali-soluble glucose, nonglucose carbohydrates, amino acids, glucosamine, galactosamine, and a compound tentatively identified as quinovosamine. The last component has not previously been observed in N. crassa cell walls. Although the cell wall dry weight content of osmotic mutants was not altered, walls isolated from all of the osmotic strains had less alkali-insoluble glucose than those from the wild type. In addition, all of the loci except cut exhibited other consistent differences from the wild type. The os-1, os-3, and os-5 mutants had low levels of alkali-soluble glucose. The os-3 and os-5 mutants had high levels of nonglucose carbohydrates, and flm-2 had a low level of nonglucose carbohydrates. The os-4 mutants had low levels of galactosamine and amino acids and high levels alkali-soluble glucose. An os-1 mutant, B135, produced less of the whole alkali-soluble fraction of the cell wall.     

Cell wall composition in Corynebacterium bovis and some other corynebacteria

The cell wall compositions of two strains of Corynebacterium bovis were found to differ: one contained lysine, rhamnose, mannose, and glucose, the other meso-alpha, epsilon, diaminopimelic acid (DAP), arabinose, galactose, and mannose. The walls of a strain of C. nephridii were characterized by l-DAP and galactose. Those of a strain of C. paurometabolum and of two strains of "lipophilic diphtheroids" contained meso-DAP, arabinose, galactose, and mannose as did walls of a reference strain of C. xerosis. The results are discussed in relation to the taxonomy of the organisms examined.     

Chemical analysis of the hyphal wall of Schizophyllum commune.

1. Purified hyphal wall fragments of Schizophyllum commune are analysed and shown to consist of glucose (67.6%), mannose (3.4%), xylose (0.2%), (N-acetyl)glucosamine (12.5%), amino acids (6.4%) and some lipid material (3.0%). 2. The previously proposed structures of two glucans located at the hyphal wall surface (Wessels et al. (1972) Biochim. Biophys. Acta 273, 346-358) were essentially confirmed using methylation analysis. The mucilaginous glucan consists of 1,3-linked beta-glucan chains with branches of single glucose units attached by beta-1,6 linkages on every third unit, on average, along the chain. The alkali soluble S-glucan is an exclusively 1,3-linked alpha-glucan. 3. The alkali-insoluble R-glucan, occurring in close association with chitin, in the inner wall layer, has been characterised by methylation analysis, X-ray diffraction, enzymatic hydrolysis with purified exo-beta-1,3-glucanase and Smith degradation. It appears to be a highly branched beta-1,3,beta-1,6-glucan and a model of this glucan is proposed. Certain parts of this highly insoluble R-glucan bear a close structural similarity to the mucilaginous glucan present at the outer wall surface and in the medium.     

Distribution and composition of lipopolysaccharides from mycoplasmas.

Polymeric carbohydrates containing glycerol and fatty acids were isolated from whole cells and membranes of mycoplasmas by hot aqueous phenol extraction and gel filtration. Lipopolysaccharides were found to occur in four species of Acholeplasma, two of Anaeroplasma, and in Mycoplasma neurolyticum. None were detected in Spiroplasma citri or in five species of Mycoplasma. All lipopolysaccharides contained both neutral and N-acylated amino sugars in ratios varying from 1:1 to 3:1. The neutral sugars found in varying distribution were glucose, galactose, and mannose. The amino sugars included fucosamine, an unidentified deoxyhexosamine, galactosamine, and glucosamine. Fucosamine and glucose were the only sugars common to all lipopolysaccharides. The fatty acids were similar to those found in the lipids of each organism.     

The structure of a glycopeptide isolated from the yeast cell wall

1. Glycopeptides containing mannose were extracted from isolated yeast cell walls by ethylenediamine and purified by treatment with Pronase and fractionation on a Sephadex column. 2. A glycopeptide that appeared homogeneous on electrophoresis and ultracentrifugation had a molecular weight of 76000, and contained a high-molecular-weight mannan and approx. 4% of amino acids. 3. The amino acid composition of the peptide was determined. It was rich in serine and threonine and also contained glucosamine. No cystine and methionine were detected. 4. The glycopeptide underwent a beta-elimination reaction when treated with dilute alkali at low temperatures. The reaction resulted in the release of mannose, mannose disaccharides and possibly other low-molecular-weight mannose oligosaccharides. During the beta-elimination reaction the dehydro derivatives of serine and threonine were formed. One of the linkages between carbohydrate and amino acids in the glycopeptide is an O-mannosyl bond from mannose and mannose oligosaccharides to serine and threonine. 5. After the beta-elimination reaction the bulk of the mannose in the form of the large mannan component was still covalently linked to the peptide. This polysaccharide was therefore attached to the amino acids by a linkage different from the O-mannosyl bonds to serine and threonine that attach the low-molecular-weight sugars. 6. Mannan was prepared from the glycopeptide and from the yeast cell wall by treatment of the fractions with hot solutions of alkali. The mannan contained aspartic acid and glucosamine and some other amino acids. The aspartic acid and glucosamine were present in equimolar amounts; the aspartic acid was the only amino acid present in an amount equivalent to that of glucosamine. Thus there is the possibility of a linkage between the mannan and the peptide via glucosamine and aspartic acid. 7. Mannose 6-phosphate was shown to be part of the mannan structure. Information about the structure of the mannan and the linkage of the glucosamine was obtained by periodate oxidation studies. 8. The glucosamine present in the glycopeptide could not be released by treatment with an enzyme preparation obtained from the gut of Helix pomatia. This enzyme released glucosamine from the intact cell wall. Thus there are probably at least two polymers containing glucosamine in the cell wall. 9. The biosynthesis of the mannan polymer in the yeast cell wall is discussed with regard to the two types of carbohydrate-amino acid linkages found in the glycoprotein.     

Cell wall composition of chlorococcal algae

The cell walls of representatives of the genera Chlorella, Monoraphidium, Ankistrodesmus and Scenedesmus contained 24–74% neutral sugars, 1–24% uronic acids, 2–16% protein and 0–15% glucosamine. Two types of cell walls could be discerned containing as main sugars either rhamnose and galactose or mannose and glucose with a lack of galactose.     

Chemical compositions of cell walls and polysaccharide fractions of spirochetes

Cellular polysaccharide fractions of various representative members of genera of the family Spirochaetaceae were obtained by the ammonium hydroxide extraction method. The sugar composition of the polysaccharide preparations was complex and many kinds of sugars such as rhamnose, fucose, ribose, xylose, mannose, galactose, and glucose were detected in all of the spirochetes tested. Of particular interest was the presence of 4-O-methylmannose as a constituent polysaccharide in members of the genus Leptospira. This sugar was not detected in the polysaccharides of Spirochaeta, Borrelia, and Treponema. The chemical compositions of cell wall fractions were also examined. 4-O-Methylmannose was detected in the cell wall polysaccharides of the genus Leptospira but not in cell walls prepared from the Spirochaeta, Borrelia, and Treponema. The diaminopimelic acid present in cell wall peptidoglycans of the genus Leptospira was meso-diaminopimelic acid (A2pm). The molar ratios of alanine, glutamic acid, A2pm, glycine, muramic acid, and glucosamine in leptospiral cell walls were found to be approximately 2:1:1:1:1:1. In contrast to the Leptospira, the peptidoglycans of genera Spirochaeta, Borrelia, and Treponema contained ornithine (Orn) but not A2pm. Since 4-O-methylmannose and A2pm were found in the cell wall fractions of genus Leptospira but not in Spirochaeta, Borrelia, or Treponema, it was suggested that the chemical compositions of the cell wall might become an important criterion for the chemotaxonomy of Spirochaetales.     

Studies on the cell wall of Chlorella I. Quantitative changes in cell wall polysaccharides during the cell cycle of Chlorella ellipsoidea

1. 1. The cell wall of Chlorella ellipsoidea was fractionated intotwo components, alkali-soluble hemicellulose and alkali-insoluble"rigid wall". The former was composed of several neutral sugars,i.e. rhamnose, xylose, arabinose, mannose and galactose, andthe latter had glucosamine as a main constituent sugar.
2. 2.Quantitative changes in both hemicellulose and "rigid wall"contents during the cell cycle were followed using synchronouslygrown cells. The two cell wall components showed markedly differentchanges. Hemicellulose increased in proportion to the enlargementof the cell surface area in the growing phase, while the "rigidwall" remained almost constant in this phase. The "rigid wall"increased only in the reproduction phase—the time of autosporeformation.

(Received September 26, 1977; )